Spectroscopic and Microscopic Investigation of Gold NanoparticleFormation: Ligand and Temperature Effects on Rate and Particle Size

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Spectroscopic and Microscopic Investigation of Gold NanoparticleFormation: Ligand and Temperature Effects on Rate and Particle Size

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ARTICLE pubs.acs.org/JACS Spectroscopic and Microscopic Investigation of Gold Nanoparticle Formation: Ligand and Temperature Effects on Rate and Particle Size Rajesh Sardar† and Jennifer S Shumaker-Parry* Department of Chemistry, University of Utah, 315 South 1400 East, RM 2020, Salt Lake City, Utah 84112, United States S b Supporting Information ABSTRACT: We report a spectroscopic and microscopic investigation of the synthesis of gold nanoparticles (AuNPs) with average sizes of less than nm The slow reduction and AuNP formation processes that occur by using 9-borabicyclo[3.3.1]nonane (9-BBN) as a reducing agent enabled a timedependent investigation based on standard UVÀvis spectroscopy and transmission electron microscopy (TEM) analyses This is in contrast to other borohydride-based syntheses of thiolate monolayer protected AuNPs which form particles very rapidly We investigated the formation of 1-octadecanethiol (ODT) protected AuNPs with average diameters of 1.5À4.3 nm By studying the progression of nanoparticle formation over time, we find that the nucleation rate and the growth time, which are interlinked with the amount of ODT and the temperature, influence the size and the size dispersion of the AuNPs High-resolution TEM (HRTEM) analyses also suggest that the nanoparticles are highly single crystalline throughout the synthesis and appear to be formed by a diffusion-controlled Ostwald-ripening growth mechanism ’ INTRODUCTION Applications in electronic and optical detection systems,1,2 device development,3À5 therapeutics,6 and catalysis7,8 have made gold nanoparticles (AuNPs) the focus of much nanoscience research The optical, electronic, and catalytic properties of metal nanoparticles are correlated with the physical characteristics of the particles, such as size9À13 and shape14À23 as well as the local dielectric environment.24À27 In addition to the optical and electronic properties, the chemical properties of AuNPs are strongly related to the core size of the particles, and as the size of the particles decreases, the fraction of the atoms present on the vertex and edge sites increases in comparison to the terrace sites.28 For example, the atoms in different sites on the nanoparticle surface substantially influence surface behavior including ligand place exchange reactions29À31 as well as the electronic properties, such as the double-layer capacitance32À41 and the anion-induced adsorption.42À44 Because of the strong interrelationship, precise control of metal nanoparticle structural properties, such as size, surface chemistry, and even crystalline character, is a key goal for fundamental studies to better understand and control the optical, electronic, chemical, and electrochemical properties of AuNPs Despite all of the synthetic work to produce metal nanoparticles, the extent of control of structural properties when particles are prepared in solution-based synthesis continues to be a challenge.45À51 The Brust two-phase synthesis and its various modifications are the most common approaches used to generate AuNPs with average diameters of 1À4 nm using NaBH4 as a reducing agent.52À61 In these synthetic methods strong stabilizing agents, such as alkyl or arylthiols, have been most commonly used to control the size of the nanoparticles In these cases, the reduction usually reaches completion within a few hundred milliseconds after addition of r 2011 American Chemical Society the strong reducing agent NaBH4 that typically is used Other than NaBH4, few other borohydride-based reducing agents have been used to synthesize stable, monodisperse AuNPs with diameters of

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